Universal Second-Order Phase Transition from Integrability to Chaos

Abstract

We report a dynamical phase transition from integrability to non-integrability in a simple oval-like billiard with boundary R(θ)=1+ε(pθ). For ε=0, the phase space is foliated by invariant curves corresponding to periodic or quasiperiodic motion, whereas for small ε a thin chaotic layer separates rotational and librational trajectories. As ε increases, this layer grows according to a well-defined scaling law whose chaotic dispersion follows ω rms,satεα, where the exponent α coincides with those of the Fermi-Ulam model, periodically corrugated waveguides, and a family of discrete mappings, revealing a universal mechanism for the onset of chaos in weakly perturbed integrable systems. The deviation of the reflection angle in the billiard, ω rms,sat, acts as an order parameter: it vanishes continuously as ε 0, signalling an ordered (integrable) phase, while its susceptibility =dω rms,sat/dε diverges, indicating a second-order phase transition. A symmetry breaking and an analytically solvable diffusion process complete the near-critical phenomenology. These results establish a unified framework for the emergence of chaos from integrability.